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Chapter 6 Work and Kinetic Energy. Work We define work by the following: The angle  is the angle between the displacement and the force.

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Presentation on theme: "Chapter 6 Work and Kinetic Energy. Work We define work by the following: The angle  is the angle between the displacement and the force."— Presentation transcript:

1 Chapter 6 Work and Kinetic Energy

2 Work We define work by the following: The angle  is the angle between the displacement and the force.

3 Constant Force If the force applied is constant then the work done becomes:

4 Units The unit for work is the joule. The letter J is used to represent a joule.

5 Example A volleyball is hit over the net. During the collision with the ball, the athlete applies a force of 150 N to the ball over a distance of 2.0 cm. Determine the work done on the ball.

6 Solution The work done is given by:

7 Hooke’s Law If a spring is stretched or compressed by a small amount, the reaction force of the spring can be expressed by Hooke’s law. The force required to stretch or compress, by Newton’s third law, is negative the above equation.

8 The work done by a spring The work done compressing a spring can be obtained by applying the general definition of work.

9 Kinetic Energy Consider an object with a force applied to it in the x-direction. We can determine the motion of the object with Newton’s second law.

10 We rewrite the second law in terms of velocity.

11 We separate variables and integrate. We note that the left side of the equation is the work done moving the object. Then:

12 The object has gained energy of motion, which we called kinetic energy and define as: The work-energy theorem states that the work done by the net force on a particle is equal to the change in kinetic energy.

13 Example An archer draws back a re-curve bow. If the draw of the bow is 1000-N and the draw length is 0.75 m, determine the maximum speed that a fired arrow would leave if its mass is 100-g.

14 Sketch

15 Free-Body Diagram F

16 Solution Once again, we can treat the bow as a Hooke’s law device. Therefore:

17 Solution cont. We can now apply the work energy theorem. The work done on the arrow by the bow is equal to the change in kinetic energy.

18 Solution cont. The speed of the arrow is:

19 Power As Jennifer pulled back on the projectile launching device in lab, she was doing work. In her attempt to cock the gun she applied a force, however small it might be, but a force none the less, through a distance. According to the work energy theorem she must have been storing energy in the spring of the gun.

20 Power Now consider the time it took Jennifer to cock the gun. 15 minutes Meanwhile, Cliff was able to cock the gun in only 12 minutes after 7 failed attempts. The energy stored each time was the same; however, something was different between the two events.

21 The rate at which energy was supplied to the gun was different for each case. This rate of energy transfer or rate of work done per unit time is called the power. The average power can be defined by the following:

22 Power The instantaneous power can be obtained by letting the time difference approach zero.

23 We can also express the power in terms of an applied force. Suppose an objects velocity changes do to an applied force. The work done during a differential amount of displacement is:

24 The power is then: If the force is constant then we get:

25 Units The unit of power in the mks system is the watt.

26 Example A body-builder curls a weight bar upward in 0.4s. If the bar weighs 240-N and the distance lifted is 0.8 m, what is the average power developed during the lift?

27 Solution The average power developed is the change in the work per unit time.


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